Novel species of fungi described in this study include those from various countries as follows: Australia, Chaetomella pseudocircinoseta and Coniella pseudodiospyri on Eucalyptus microcorys leaves, Cladophialophora eucalypti, Teratosphaeria dunnii and Vermiculariopsiella dunnii on Eucalyptus dunnii leaves, Cylindrium grande and Hypsotheca eucalyptorum on Eucalyptus grandis leaves, Elsinoe salignae on Eucalyptus saligna leaves, Marasmius lebeliae on litter of regenerating subtropical rainforest, Phialoseptomonium eucalypti (incl. Phialoseptomonium gen. nov.) on Eucalyptus grandis × camaldulensis leaves, Phlogicylindrium pawpawense on Eucalyptus tereticornis leaves, Phyllosticta longicauda as an endophyte from healthy Eustrephus latifolius leaves, Pseudosydowia eucalyptorum on Eucalyptus sp. leaves, Saitozyma wallum on Banksia aemula leaves, Teratosphaeria henryi on Corymbia henryi leaves. Brazil, Aspergillus bezerrae, Backusella azygospora, Mariannaea terricola and Talaromyces pernambucoensis from soil, Calonectria matogrossensis on Eucalyptus urophylla leaves, Calvatia brasiliensis on soil, Carcinomyces nordestinensis on Bromelia antiacantha leaves, Dendryphiella stromaticola on small branches of an unidentified plant, Nigrospora brasiliensis on Nopalea cochenillifera leaves, Penicillium alagoense as a leaf endophyte on a Miconia sp., Podosordaria nigrobrunnea on dung, Spegazzinia bromeliacearum as a leaf endophyte on Tilandsia catimbauensis, Xylobolus brasiliensis on decaying wood. Bulgaria, Kazachstania molopis from the gut of the beetle Molops piceus. Croatia, Mollisia endocrystallina from a fallen decorticated Picea abies tree trunk. Ecuador, Hygrocybe rodomaculata on soil. Hungary, Alfoldia vorosii (incl.Alfoldia gen. nov.) from Juniperus communis roots, Kiskunsagia ubrizsyi (incl. Kiskunsagia gen. nov.) from Fumana procumbens roots. India, Aureobasidium tremulum as laboratory contaminant, Leucosporidium himalayensis and Naganishia indica from windblown dust on glaciers. Italy, Neodevriesia cycadicola on Cycas sp. leaves, Pseudocercospora pseudomyrticola on Myrtus communis leaves, Ramularia pistaciae on Pistacia lentiscus leaves, Neognomoniopsis quercina (incl. Neognomoniopsis gen. nov.) on Quercus ilex leaves. Japan, Diaporthe fructicola on Passiflora edulis × P. edulis f. flavicarpa fruit, Entoloma nipponicum on leaf litter in a mixed Cryptomeria japonica and Acer spp. forest. Macedonia, Astraeus macedonicus on soil. Malaysia, Fusicladium eucalyptigenum on Eucalyptus sp. twigs, Neoacrodontiella eucalypti (incl. Neoacrodontiella gen. nov.) on Eucalyptus urophylla leaves. Mozambique, Meliola gorongosensis on dead Philenoptera violacea leaflets. Nepal, Coniochaeta dendrobiicola from Dendriobium lognicornu roots. New Zealand, Neodevriesia sexualis and Thozetella neonivea on Archontophoenix cunninghamiana leaves. Norway, Calophoma sandfjordenica from a piece of board on a rocky shoreline, Clavaria parvispora on soil, Didymella finnmarkica from a piece of Pinus sylvestris driftwood. Poland, Sugiyamaella trypani from soil. Portugal, Colletotrichum feijoicola from Acca sellowiana. Russia, Crepidotus tobolensis on Populus tremula debris, Entoloma ekaterinae, Entoloma erhardii and Suillus gastroflavus on soil, Nakazawaea ambrosiae from the galleries of Ips typographus under the bark of Picea abies. Slovenia, Pluteus ludwigii on twigs of broadleaved trees. South Africa, Anungitiomyces stellenboschiensis (incl. Anungitiomyces gen. nov.) and Niesslia stellenboschiana on Eucalyptus sp. leaves, Beltraniella pseudoportoricensis on Podocarpus falcatus leaf litter, Corynespora encephalarti on Encephalartos sp. leaves, Cytospora pavettae on Pavetta revoluta leaves, Helminthosporium erythrinicola on Erythrina humeana leaves, Helminthosporium syzygii on a Syzygium sp. barkcanker, Libertasomyces aloeticus on Aloe sp. leaves, Penicillium lunae from Musa sp. fruit, Phyllosticta lauridiae on Lauridia tetragona leaves, Pseudotruncatella bolusanthi (incl. Pseudotruncatellaceae fam. nov.) and Dactylella bolusanthi on Bolusanthus speciosus leaves. Spain, Apenidiella foetida on submerged plant debris, Inocybe grammatoides on Quercus ilex subsp. ilex forest humus, Ossicaulis salomii on soil, Phialemonium guarroi from soil. Thailand, Pantospora chromolaenae on Chromolaena odorata leaves. Ukraine, Cadophora helianthi from Helianthus annuus stems. USA, Boletus pseudopinophilus on soil under slash pine, Botryotrichum foricae, Penicillium americanum and Penicillium minnesotense from air. Vietnam, Lycoperdon vietnamense on soil. Morphological and culture characteristics are supported by DNA barcodes.
The enzyme L-asparaginase (L-ASNase) is used in the treatment of Acute Lymphoblastic Leukemia. The preparations of this enzyme for clinical use are derived from bacterial sources and its use is associated with serious adverse reactions. In this context, it is important to find new sources of L-ASNase. In this work, the Placket-Burman Experimental Design (PBD) was used to determine the influence of the variables on the L-ASNase production then it was followed by a 28–4 Factorial Fractional Design (FFD). The results obtained from PBD have shown a range of L-ASNase activity, from 0.47 to 1.77 U/gcell and the results obtained from FFD have showed a range of L-ASNase activity, from 1.10 to 2.36 U/gcell. L-proline and ammonium sulfate were identified as of significant positive variables on this production enzyme by Penicillium cerradense sp. nov. The precise identification of this new species was confirmed by morphological characteristics and sequence comparisons of the nuclear 18S-5.8S-28S partial nrDNA including the ITS1 and ITS2 regions, RNA polymerase II, β-tubulin and calmodulin genomic regions. The genetic sequence coding for the L-ASNase was obtained after carrying out a full genome sequencing. The L-ASNase expressed by P. cerradense sp. nov may have promising antineoplastic properties.
Crotalaria breviflora (Fabaceae) is used as green manure crop because of its nitrogen fixation and nematode control (Nascimento et al. 2020). In April 2018, leaf wilting, flower rot, and stem necrosis symptoms were observed on C. breviflora with 100% incidence, in Sorriso (12° 33′ 31″ S, 55º 42′ 51″ W), Santa Carmem (11° 55′ 52″ S, 55º 16′ 47″ W), and Sapezal (12º 59′ 22″ S, 58º 45′ 52″ W) counties in the state of Mato Grosso, Brazil. Three monosporic isolates were isolated from symptomatic leaves, cultivated in potato dextrose agar (PDA) medium, and deposited at the Cultures Collection of the University of Brasilia (codes CCUB 1293, CCUB 1667, CCUB 1668). Colonies on PDA were white and cottony with presence of hyaline and coenocytic hyphae. The mycelia later became pale yellow with abundant reproductive structures. Sporangiophores were hyaline, aseptate, unbranched, and apically dilated to form a clavate vesicle, which produced secondary vesicles bearing sporangiola. Secondary vesicles were clavate, light brown, and 37 to 51 µm in diameter. Sporangia were brown to dark brown, globular to ellipsoid, 115 to 140 µm long, and 96 to 122 µm wide. Sporangiospores (n=30) were brown to reddish-brown, ellipsoid to ovoid, with longitudinal striae, 14 to 19 µm long, and 8 to 12 µm wide. Some with hyaline appendages at both ends. Their morphological characteristics were consistent with the descriptions of Choanephora cucurbitarum (Kirk 1984). To confirm the identity, the DNA of the three isolates was extracted and the sequences of Small Subunit (SSU), Large Subunit (LSU), and complete Internal Transcribed Spacer (ITS) of rDNA were amplified using V9G, ITS3, and LR5 primers (GenBank acc. no: MN897836, MN897837 and MN897838). The sequences were aligned with the MAFFT software. The alignment matrix was subjected to Maximum Likelihood (ML) analysis using RAxML v. 8 and Bayesian Inference performed in MrBayes v.3.1.2. The tree was edited in the FigTree software. The sequences showed 100% identity with the sequences from C. cucurbitarum found on the GenBank. To confirm pathogenicity, a suspension at 5.4 ×106 spores/ml was prepared from a 15-day-old culture grown at 25°C and sprayed on asymptomatic plants of C. breviflora. Sterilized water was sprayed as the control. Plants were kept in a humid chamber at 20°C for 48 h. Initial symptoms were visualized 16 days after inoculation. Complete necrosis of leaves and stems with spore mass on infected tissue was observed 19 days after inoculation. To satisfy the Koch’s postulates, the fungus was successfully reisolated from the infected tissues. No symptoms were observed on the control plants. In Brazil, this pathogen has been reported on Brassica oleracea var. capitata, Capsicum annuum, Crotalaria spectabilis, Cucurbita sp., and Vigna unguiculata (Alfenas et al. 2018; Mendes and Urben, 2019). C. cucurbitarum has been reported to have a wide range of hosts (Farr and Rossman, 2020). It can infect the crops grown in rotation or in succession, including common bean, corn, cotton, quinoa, soybean, and sunflower. Therefore, this pathogen is of epidemiological importance and poses a threat to the croplands where environmental conditions are conducive to the disease to develop and spread. To our knowledge, this is the first report of C. cucurbitarum causing leaf and flower wilt, and stem rot on C. breviflora in the world. Acknowledgment We thank the Environmental Sciences Graduate Program, Federal University of Mato Grosso, University of Brasilia, PROPeq/PROPG-UFMT, EMBRAPA, CODEX/UFMT, Institute of Agricultural and Environmental Sciences (ICAA)/UFMT and CAPES for providing the Master's scholarship. References Alfenas, R. F., et al. 2018. Plant Dis.102:1456. https://doi.org/10.1094/PDIS-10-17-1610-PDN, Google Scholar. Farr, D. F., and Rossman, A. Y. 2020. Fungal Databases, Syst. Mycol. Microbiol. Lab., ARS, USDA. Retrieved May 26, 2020 from https://nt.ars-grin.gov/fungaldatabases/, Google Scholar. Kirk, P. M. 1984. Mycol Paper. 152:1. Google Scholar. Mendes, M. A. S., and Urben, A. F. 2020. Fungos relatados em plantas no Brasil, Retrived May 26, 2020 from http://pragawall.cenargen.embrapa.br/aiqweb/michtml/fgbanco01.asp, Google Scholar. Nascimento, D. D. et al. 2020. Bioscience Journal. 36:713. https://doi.org/10.14393/BJ-v36n3a2020-42248, Google Scholar.
Calonectria-leaf-blight (CLB) caused by Calonectria spp. is one of the main foliar disease of eucalypt plantation in Brazil. Recent studies have shown the potential impact of this disease and the hyper-diversity in the pathogen population. However, there are no studies addressing the occurrence and identification of Calonectria species in Mato Grosso state, Brazil. The aims of this study were to conduct surveys of soils and trees in eucalypt plantation in southeast of Mato Grosso and identify which species are dominant by DNA sequence analyses. The phylogenetic analyses were performed by using partial sequences of translation elongation factor 1-α (tef1a), β-tubulin (tub2), calmodulin (cal) and histone H3 (his3) gene regions. A great variability in Calonectria was observed in the Mato Grosso state, since different phylogenetic groups were found in a survey from a single collection place. Based on multigene phylogenetic analyses, a new phylogenetic lineage is proposed (Calonectria sp. new.), Calonectria pteridis is reported in Eucalyptus urophylla in Mato Grosso, and the occurrence of Calonectria pseudometrosideri causing CLB on Eucalyptus spp. is reported for the first time in the world.Keywords: forest pathology, Cylindrocladium, eucalyptus farming, planted forest.Nova linhagem filogenética de Calonectria causando mancha foliar em Eucalyptus urophylla em Mato Grosso RESUMO: A mancha-de-calonectria causada por Calonectria spp. é uma das principais doenças foliares da cultura do eucalipto no Brasil. Estudos recentes têm mostrado o potencial impacto dessa doença e a enorme variabilidade existente na população do patógeno. No entanto não há estudos sobre ocorrência e a identificação de espécies de Calonectria no estado de Mato Grosso. Assim, os objetivos desse trabalho foram fazer um levantamento das espécies de Calonectria que ocorrem no sudeste de Mato Grosso e identificar por meio de análises de sequência de DNA, quais espécies são predominantes. As análises filogenéticas foram realizadas com sequencias parciais dos genes fator de elongação (tef1a), β-tubulina (tub2), calmodulina (cal) e histona H3 (his3). Foi observada uma grande variabilidade de Calonectria no estado de Mato Grosso, uma vez que foram encontrados diferentes grupos filogenéticos em isolados obtidos a partir de um único local de coleta. Com base na análise filogenética multi-gênica, uma nova linhagem filogenética é proposta (Calonectria sp. new.), Calonectria pteridis é encontrada em Eucalyptus urophylla no Mato Grosso, e relata-se pela primeira vez no mundo a ocorrência de Calonectria pseudometrosideri causando a mancha-de-calonectria em Eucalyptus spp.Palavras-chave: patologia florestal, Cylindrocladium, floresta plantada, mancha-foliar.Recebido em outubro/2015; Aceito em março/2016.
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